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Revolutionary Insights into Space-Time by Raghu Kulkarni

Raghu Kulkarni, the CEO of IDrive Inc. and an independent researcher, has made waves in the scientific community with his revolutionary conceptual framework regarding the structure of the universe, known as the Selection-Stitch Model (SSM). In what seems to be a direct counter to Albert Einstein's assertion that "God does not play dice," Kulkarni asserts instead that indeed, "God plays dice!" This not-so-subtle shift in perspective aims to reframe our understanding by proposing that space-time is not a smooth continuum as traditionally thought, but rather a complex tapestry woven from discrete units of quantum information termed voxels.

Paradigm Shift in Understanding the Universe

The implications of the SSM are profound; it asserts that prior to the emergence of space-time, nature engaged in an intricate sampling of countless random logical combinations. This phase effectively reflects the essence of quantum mechanics, ultimately leading to the solidification of our observable universe as we know it. In Kulkarni's model, the vacuum of space operates as an active miner, constantly processing quantum fluctuations and stitching these into the cosmic fabric, which he describes through the concept of a "Steady-State Informational Miner."

Information Mining and Universe Growth

One of the core tenets of the SSM is its assertion that space-time is a manifestation of effective entanglement entropy. The model elucidates how the process of entanglement contributes to the expansion of the universe, portraying it not as a backdrop but rather as an evolving entity. By employing a unique "Stitch Operator" that links information, new spatial volume is created, which in turn delineates a continuous process of cosmic growth.

Addressing Contemporary Challenges in Astrophysics

In moving beyond Einstein's view of space-time as a smooth, static entity, Kulkarni's SSM also addresses current challenges in astrophysics such as the so-called "Hubble Tension," which has perplexed astronomers regarding the expansion rate of the universe. Kulkarni introduces the concept of Lattice Pressure to resolve this issue, suggesting a cosmic mesh reaching a critical packing limit, thereby pushing outward and resulting in an observed increase in the expansion rate by approximately 8.3% correlating with recent observational data from 2026.

Dark Matter Unveiled Through Geometry

Additionally, the SSM introduces the 51 Dark Matter-to-baryon ratio achieved through 3D geometric principles. In this perspective, regular matter traverses one axis of the lattice while energy contained in additional axes manifests as dark matter. This model not only disrupts traditional understandings but provides a framework for classifying elusive dark matter—and perhaps most intriguingly, it raises questions surrounding the fate of black holes.

Re-defining Black Holes and the Information Paradox

Moving away from Stephen Hawking's surface-based radiation model, the SSM offers insights regarding black holes that significantly alters our comprehension of the Information Paradox. Kulkarni proposes the idea of "Bulk Un-Stitching," whereby information dissipation occurs from the entire volume of a black hole instead of solely from its surface. This innovative approach explains the absence of Primordial Black Holes, which NASA's BlackCAT telescope has not detected in 2026; they would have long evaporated due to this new understanding of un-stitching.

Technical Validation and Future Implications

Kulkarni backs his revolutionary model with three key scientific papers that delve into various aspects of the SSM, including discussions on quantum entanglement and its role in space-time emergence and expansion. These technical explorations lend considerable credence to his theories and their applicability to contemporary physics.

In conclusion, Kulkarni’s Selection-Stitch Model marks a significant advancement in our understanding of the universe, prompting a shift in perspectives and theories that have long stood unchallenged. As he states, "The Selection-Stitch Model moves us away from viewing space as an empty stage and toward viewing it as a dynamic, emergent structure of quantum information." Through the lens of this model, scientists may find answers to some of the most pressing questions about our universe's origins, composition, and fate.